This channel is absolutely fantastic. I know a lot of what you go over, especially with fluid-dynamics, but you always have some little known information. My favorite was the concrete episode. Keep it up man!
I'm a contractor. My current job is replacing a hot tub built into a basement remodel thirty years ago. With no room to bring in a new hot tub I suggested a whirlpool bath, an idea the client accepted. The biggest problem was that the hot tub had no drain, water was pumped into the adjacent shower pan when it needed to be refreshed. To overcome this I built a platform with the drain running between it and the concrete floor, through the shower wall, over the top of the existing shower pan. I was worried about water velocity because of the 20" head pressure. The drain leaves the tub with 1.5" PVC into a trap then travels at a gentle slope, 1/2" in four feet. As it enters the wall it steps up to 2" then flows out of a 3" shower pan drain with grill that is acting in reverse, water coming out horizontally instead of entering vertically. The volume is very impressive as is the sound. It is dispersed enough that it does not splash excessively, I think the grill helps a lot. I was quite pleased. Here is what I did not expect. The flow from the 1.5" pipe overwhelms the 2" shower drain. Water depth in the pan gradually increases to about 3", near overflow. Then the most remarkable phenomenon and the reason I write. A tremendous whirlpool is created at the drain, 3" deep 2" diameter. No water goes down the center of the drain. By coincidence I am reading a book "The Science of Leonardo". He would have loved it. With the ceiling light of the shower shining through the turbulence the patterns are stable and clear. I will cut a rubber washer to insert under the "popup" to reduce the flow. I think that will do the trick. We'll see. Thanks for your excellent videos.
I used this video as reference with my customers who have issues with flooding basements. By creating a hydraulic JUMP at the base of the roof's gutter system's down spouts, we achieved sucess by eliminating scour, with out digging a complex underground drain system. THIS CHANNEL HAS EXTREMELY HIGH QUALITY CONTENT. MY CUSTOMERS ARE DELIGHTED.
We also observe hydraulic jumps in atmospheric science. They often happen downstream of mountain rages when mountain waves break. Super critical flow trapped above an inversion layer can transition to sub critical and cause deep mixing of the boundary layer. This mixing transports high winds to the surface in addition to the turbulence being induced by the terrain. This can lead to intense downslope windstorms also called chinook or fohn winds. Where I work in Wyoming, we often see wave breaks and hydraulic jumps produce damaging wind gusts over 100 mph.
@@trucid2 essentially the same way as explained through here. Air is a fluid so it behaves the same as water or other fluids but with different viscosity.
@trucid2 Wave speed is just the speed at which a longitudinal wave (such as sound) travels through a fluid. This speed is generally constant for a fluid. What changes is the speed at which the fluid itself is flowing. So if air were moving very quickly at a place and then coming to an abrupt halt, that place would have a hydraulic jump of air.
I don't general comment on videos but I wanted to say how much I love how you handle your sponsorship ads. They don't interrupt your videos and are extremely well done and to the point. I even found myself watching them and I am even considering getting VPN just to support you. You sure as hell deserved it. Thank you and keep up the fantastic work!
Especially since he mentioned how some rec facilities use hydraulic jumps. Makes me nervous to think of some dumb amateur kayaker looking for a spot of turbulence for fun. Designed facilities are not the same thing as found facilities, folks!
I will respectfully watch every single ad and like all the videos, I absolutely love your content and you deserve all my support! Thank you for this amazing knowledge and thanks to you I am walking down a Engineering path!
Everything you publish is first class. You can really communicate the concepts to people. It's geeky, but makes me proud to be an engineer. If these were shown to high school students, they might choose different fields of work that make them happier. Kudos to you!
And yet again, you post a video that makes supposedly complicated and abstract things so easy to understand. Brilliant! don't stop being you and amazing. x
In the process of researching the failure of the Oroville dam's main spillway in 2017, I read up on the earlier 2009 failure of their River Valve Outlet System, which involved a hydraulic jump. Their RVOS pulls water from the lowest/coldest point of the reservoir where it flows through a tunnel to a point under the dam near the turbine outlets (head pressure at about 300psi), and then can be released through a cone valve into another long tunnel that is joined by water from the turbine outlets (the tailrace). RVOS is designed to maintain minimum flow in the river when the reservoir drops below the turbine inlets and to regulate temperature for fish in the river. Oroville's Hyatt power plant is a pumping power station so the turbine outlets are submerged in their own trailrace which can either flow out into the Thermalito Diversion Pool, or pull water back from it when the turbines run as pumps. The tailrace consists of two 35ft diameter, 2000ft long tunnels. One is fully submerged, the other half full and they're cross joined. RVOS cone valves output into the half full tunnel at *extremely* high pressures and flow rates. Normally it blasts the water onto an angled steel dispersion ring which absorbs the high velocity flow from the valves, to merge it more smoothly with the low velocity flow of the half filled tunnel. The ring had been damaged due to many years of use so earlier in 2009, they removed it.. (presumably with intent to replace). Then a few months later management thought it would be interesting to conduct a test to open the RVOS valve to 100% to see what effect it would have (1. they'd been told never to run it at 100% due to prior damage 2. design specs said RVOS was never to be operated without dispersion ring). The manually operated control (just a big wheel) for the RVOS cone valve sits in a chamber connected through a long person tunnel up into the inner turbine room, and that chamber is separated from the ring valve outlet by a fully sealed 20ft tall steel wall. That wall was designed to fail with 15ft of head pressure behind it in the unlikely event that the manual control valve failed and let water into that chamber. This wall failure would prevent water from backing up the person tunnel into the turbine room. So.. 5 people enter the control room, and start to open the RVOS valve up to 100%. At 85% all hell breaks loose. The valves release about 4-5K CFS of water at extremely high velocity into a half filled tunnel, and without the dispersion ring this accelerates the velocity of the water in the tunnel for a few hundred feet. During original design (including extensive small scale testing), they realized that even with the dispersion ring a hydraulic jump could form as high velocity flow meets low, that might reach up to the roof of the tunnel, which could cause a vacuum condition in the tunnel upstream of the jump. So they built in a vent in the roof several hundred feet down the tunnel connected by a large tube running back to another vent in the cone valves outlet chamber. Idea being that if the jump formed between the two vents sealing the tunnel it could still equalize the air pressure on either side of it. But without the dispersion ring in place, the jump moved much further down the tunnel than design called for, and blocked the lower vent. This caused a siphon pump effect back to the valve outlet chamber, eventually causing high enough vacuum that the steel wall designed to hold back 15ft of water, blew out into the tunnel almost taking the 5 people in that chamber with it. Doors further up the man tunnel also failed and debris was sucked down that tunnel pelting the people in the chamber now open to raging water and continuing vacuum. With hurricane force winds coming from the person tunnel through the chamber into the RVOS outlet someone managed to turn off the valve to stop the flow. One person was seriously injured. RVOS was repaired in 2014, and operated again that year when drought conditions dropped the reservoir below the turbine inlets.
So what consequences did management face for reckless endangerment of 5 lives? Let me guess... a raise, promotion, transfer, or all three of the above.
@@allencummings7564 Short answer. They're idiots. Long answer according to the investigative report afterwards.. ""DWR removed the baffle ring in April 2009, four months before the test. It did so without consulting its Division of Dam Safety, which should have approved that action first. The test was ordered because DWR “wanted to determine the destructive effects” of opening the valves to 100 percent, according to the investigation."' Mission accomplished.
I'm a kayaker and I clicked on this video because it reminded me of rapids and whitewater in rivers and then you explained it and even mentioned how we kayakers use this physical phenomenon to have fun! You explained it perfectly! Great video!
Another great video! The only thing I would have added is a little discussion about what the Froude number is in various flow regimes. It would be useful for Civil students and others interested in understanding these things.
I have an undergraduate degree in chemical engineering, a graduate degree in mechanical engineering, and another graduate degree in aerospace engineering where I studied hypersonic air breathing propulsion. And yet I learned absolutely NOTHING about hydraulic jump in school. I love learning new things so thank you so much for this video. :)
Really nice explanation of the jump. I 'm an engineer for NJ and our erosion control program (urban; construction, storm water etc) deals with scour protection all the time. I'm going to forward a link to your video to our soil conservation districts for them to watch!
I would imagine (in a dam example) that because the slipway and hydraulic jump section is generally exposed or near surface close to the dam, it is easy to work on it there and maintain or replace damaged sections, rather than trying to repair erosion downstream.
I suppose that, since the structure is already in that turbulence zone he is talking about (since the hidraulic jump starts ahead of the structure), the effects of the erosion had already stopped being important before that structure.
“This is the definition of engineering…” That was truly beautiful. Non- technical people might not realize that there is elegance and beauty in engineering. It blows me away sometimes.
Fascinating. thank you. I have a white water centre near me in Nth london and on my visits observing the canoeists i noticed that when exiting a 'rapid' they actually stayed where they were and didn't get pushed downstream. I was puzzled. I found your video and it goes some way to explaining why. Thanks again.
When you see ocean waves coming on shore and then retreating, you can see a 'battle' between the receding and approaching waves, as mentioned in the video. Is that also a hydraulic jump? If yes, which is the tranquil bit and which is the fast bit?
Hey! I can see the dam on the Mississippi at 5:55 from my house! :) When he talked about the energy dissipation over a dam, I immediately thought of this one, because during snow melt in the spring, the river gets going really fast and the flowing water makes beautiful plumes of white water when it hits the bottom of the spillway.
5:55 that's where I live, Saint Anthony Falls on the Mississippi River in Minneapolis! I pass over that bridge on my way home every day and I love watching the water flow!
From what I can tell, the main difference is the density of the fluid medium. The principles seem the same, they just happen at much lower speeds in water.
Same here. If you're feeling adventurous, check out this video. It starts out fascinating, but wait for what happens after the cameraman zooms onto the stairwell a couple minutes in: ua-cam.com/video/fJVBlhgt9j8/v-deo.html It's during a regular test that shuts a valve near the turbine and what you see is holding tank to prevent a water hammer (which can cause damage to the water tunnels) from forming when the water tunnels to the turbine are closed. The uploader works at that dam, so check out his other videos, including down that hole on the right and a device (located up the incline) that is lowered down it to remove/replace the turbine blades.
Hello from the Dayton, Ohio area, where your footage around 1:50, 3:20, 5:22ish and 6:40 come from. Seeing that you report to be in Texas, these random shots from my local parks were an enjoyable surprise. :)
Glad to have a civvie who can explain open channel flow to this mechie. I've had a few false starts on reading up on hydraulic jump, but never really got anywhere. I've seen the sink example, but it didn't really give great insight like tying in subcritical and supercritical flow. Also, I definitely experienced some low-key anxiety from the shot of the bellmouth spillway with the viewing platform right over the middle. Nothing like rolling a little acrophobia, bathophobia, submechanophobia, and a residual childhood fear of drains all into one! I also feel completely compelled to visit someday ... where is it?
Critical flow is also a very unstable condition that engineers seek to avoid when designing channels. You would ideally design the channel so that either the sub or super critical flow dominates, because as you approach critical flow conditions, the system as a whole becomes increasingly unpredictable
I've just discovered this channel - I always wanted to be a Civil Engineer but ended up as a Chartered Surveyor - This channel is excellent and reinforces my view - I should have been a CEng.
That hydraulic jump at 3:58 propagates just like a normal shock. This is so cool--I've never seen the analogy with supersonic flow so clearly! Just replace the sound speed with the surface wave velocity. So this really is rocket science!
Right. Like I said, it's intuitive and easy. This video tries to make it seem like something surprising. There are a lot of things in physics that I do find surprising. In fluid dynamics, I'd go with the Venturi effect and Mach diamonds. Elsewhere, gyroscopic precession, quantum locking. But this video spent nine breathless minutes saying "water piles up and the slow part ends up on top."
He was referring to dams with dissipation on the downstream side which prevent an abrupt hydraulic jump and prevent a retentive hole from forming to avoid erosion (and avoid a severe drowning hazard)
Hi! I'm a whitewater kayaker who's tried some playboating in the past. It's super fun. I'm really glad you mentioned it in this video :) Thanks for posting!
Lower Huia Dam near Auckland, New Zealand. Found this in another post and verified with a Google search. www.cs.auckland.ac.nz/~bwue001/Tramping/LowerHuiaDamCircle/LowerHuiaDamCircle.html
This guy's channel and its demonstration + crash course fan facts and animation + kurzgezagt philosophical approach and animation + khan academy/organic chemistry examples = ultra ideal tutorial video
I am so glad I found this channel. I've been fascinated by dams, weirs, watermills and basically everything that has something to do with large masses of water since I can remember.
I just wanna lay in your lap and soak up your knowledge and calming voice all night. Very informative video. I never imagined the fluid dynamic of a dam being as complex as you have exposed it to be.
TheKazragore yeah well... I wasn’t aware that these were dangerous before a few years ago, they seem not completely friendly, but they are far more deadlier that they actually look... once you get stuck in one, you don’t get out
All kidding aside, the dangers of hydraulic jumps are not immediately obvious, and many of those killed are rescue personnel and even those trying to recover the bodies of rescue personnel.
As I'm seeing it, knowledge of what's happening mitigates most of the danger. Like with rip currents; for scuba divers they're a free ride out. The difference between safe and not is in recognizing and understanding what's going on. Without trying to be judgy, what makes things dangerous is ignorance and stupidity.
Ooh you did the video finally. Maybe you'll do another What's that Infrastructure video soon? I would also love to see more geotechnical videos with models like the internal erosion, ground water flow, and reinforced soil videos.
Awesome video. With simple but deep principles with far reaching real life implications, all explained in a compelling way. Thanks!!! Just one note: gravity waves velocity is how fast pressure pressure disturbance travel --> how fast *hydrostatic* (or nearly hydrostatic) pressure disturbance travel (otherwise: sound speed is how fast pressure disturbance travel).
Hi - Glad this came up on my YTube this morning. We have to design a drainage line from an uphill neighbor and I know some sort of gentling pond will be needed at the base of the steeper slope. This vid is helpful. A much smaller scale project, but "the principle is the same."
@Sunyata I know, but here again you also fail to explain what the 'jump' is. If you're going to try and explain something, maybe stand back a bit and look objectively at what you're saying. It's called a 'jump' because the surface level of the water just beyond the flow intersect is HIGHER at the sub-critical flow rate than it is at the critical flow that feeds it. 101
"Fluid dynamics might sound as comlicated as rocket science..." Boy i wish it was. Rocket science is weak shit when compared to fluid dynamics. There's a reason why theres still a Millenium problem open on the Navier Stokes equation.
I like to have dangerous superficial knowledge! ;-) You explain things so well, that I think to understand complex things after 5 minute videos. Thanks a lot, you motivated to read books about fluid mechanics as a telecommunication engineer.
Great video. I just took my Fluid Mechanics course and am now taking Environmental Engineering course and this video was a great explanation of sub/super critical flow. 👍🏽
This channel is absolutely fantastic. I know a lot of what you go over, especially with fluid-dynamics, but you always have some little known information. My favorite was the concrete episode. Keep it up man!
When I found this channel I was binge watching his video it one of the best educational channel out their
I know nothing about any of this, but still find it super fascinating!
pererau Same here
I'm a contractor. My current job is replacing a hot tub built into a basement remodel thirty years ago. With no room to bring in a new hot tub I suggested a whirlpool bath, an idea the client accepted. The biggest problem was that the hot tub had no drain, water was pumped into the adjacent shower pan when it needed to be refreshed. To overcome this I built a platform with the drain running between it and the concrete floor, through the shower wall, over the top of the existing shower pan.
I was worried about water velocity because of the 20" head pressure. The drain leaves the tub with 1.5" PVC into a trap then travels at a gentle slope, 1/2" in four feet. As it enters the wall it steps up to 2" then flows out of a 3" shower pan drain with grill that is acting in reverse, water coming out horizontally instead of entering vertically. The volume is very impressive as is the sound. It is dispersed enough that it does not splash excessively, I think the grill helps a lot. I was quite pleased.
Here is what I did not expect. The flow from the 1.5" pipe overwhelms the 2" shower drain. Water depth in the pan gradually increases to about 3", near overflow. Then the most remarkable phenomenon and the reason I write. A tremendous whirlpool is created at the drain, 3" deep 2" diameter. No water goes down the center of the drain. By coincidence I am reading a book "The Science of Leonardo". He would have loved it. With the ceiling light of the shower shining through the turbulence the patterns are stable and clear.
I will cut a rubber washer to insert under the "popup" to reduce the flow. I think that will do the trick. We'll see. Thanks for your excellent videos.
It would actually be cool to see a video of this if you managed to record one.
I used this video as reference
with my customers who have issues with flooding basements.
By creating a hydraulic JUMP at the base of the roof's gutter system's down spouts, we achieved sucess by eliminating scour, with out digging a complex underground drain system.
THIS CHANNEL HAS EXTREMELY HIGH QUALITY CONTENT. MY CUSTOMERS ARE DELIGHTED.
We also observe hydraulic jumps in atmospheric science. They often happen downstream of mountain rages when mountain waves break. Super critical flow trapped above an inversion layer can transition to sub critical and cause deep mixing of the boundary layer. This mixing transports high winds to the surface in addition to the turbulence being induced by the terrain. This can lead to intense downslope windstorms also called chinook or fohn winds. Where I work in Wyoming, we often see wave breaks and hydraulic jumps produce damaging wind gusts over 100 mph.
How is sub and supercritical flow defined for air?
@@trucid2 essentially the same way as explained through here. Air is a fluid so it behaves the same as water or other fluids but with different viscosity.
@@TwisterKidMedia He defined it in terms of wave speed. How would that work for air?
@@trucid2 Never heard of supersonic storms before? 😂
@trucid2 Wave speed is just the speed at which a longitudinal wave (such as sound) travels through a fluid. This speed is generally constant for a fluid. What changes is the speed at which the fluid itself is flowing. So if air were moving very quickly at a place and then coming to an abrupt halt, that place would have a hydraulic jump of air.
Very interesting indeed! Thanks for posting.
Yo what’s up
I’m subbed to you
Absolutely one of the best channels on UA-cam!
remember to like and comment to help with the internal algorithm and help grow his channel :P
well one of the best engineering channels.
Practical Engineering and Smarter Everyday are my two favorite mind engaging channels. It doesn't get any better than these😃
Practical engineering and mark Rober are some of my favorite UA-camrs
@@Kansasavation me too! I’m very interested in engineering, architecture, and science
"I owe me marriage to VPNs"
Okay hold up where is this going
He's literally Nord VPN Man
I don't general comment on videos but I wanted to say how much I love how you handle your sponsorship ads. They don't interrupt your videos and are extremely well done and to the point. I even found myself watching them and I am even considering getting VPN just to support you. You sure as hell deserved it.
Thank you and keep up the fantastic work!
Perhaps you could show a study of the dangers of low head dams?
The drowning machine!
An intresting video presentation by Ed Kern from 2013: "Fatal Currents - Low Head Dam Presentation" (ua-cam.com/video/XsYgODmmiAM/v-deo.html)
Especially since he mentioned how some rec facilities use hydraulic jumps. Makes me nervous to think of some dumb amateur kayaker looking for a spot of turbulence for fun. Designed facilities are not the same thing as found facilities, folks!
@@msaynevirta Thank you for the link. This video definitely reminda me of that presentation.
Also known as a weir
Very enjoyable. No flashing images and loads of crappy music - just the facts and a practical demo. Thankyou!
Fascinating. I got absorbed into the video and ended up in a calm place (the atmospheric music and friendly manners helped a lot). Thank you grady
I will respectfully watch every single ad and like all the videos, I absolutely love your content and you deserve all my support! Thank you for this amazing knowledge and thanks to you I am walking down a Engineering path!
Everything you publish is first class. You can really communicate the concepts to people. It's geeky, but makes me proud to be an engineer. If these were shown to high school students, they might choose different fields of work that make them happier. Kudos to you!
And yet again, you post a video that makes supposedly complicated and abstract things so easy to understand. Brilliant! don't stop being you and amazing. x
In the process of researching the failure of the Oroville dam's main spillway in 2017, I read up on the earlier 2009 failure of their River Valve Outlet System, which involved a hydraulic jump. Their RVOS pulls water from the lowest/coldest point of the reservoir where it flows through a tunnel to a point under the dam near the turbine outlets (head pressure at about 300psi), and then can be released through a cone valve into another long tunnel that is joined by water from the turbine outlets (the tailrace). RVOS is designed to maintain minimum flow in the river when the reservoir drops below the turbine inlets and to regulate temperature for fish in the river. Oroville's Hyatt power plant is a pumping power station so the turbine outlets are submerged in their own trailrace which can either flow out into the Thermalito Diversion Pool, or pull water back from it when the turbines run as pumps. The tailrace consists of two 35ft diameter, 2000ft long tunnels. One is fully submerged, the other half full and they're cross joined. RVOS cone valves output into the half full tunnel at *extremely* high pressures and flow rates. Normally it blasts the water onto an angled steel dispersion ring which absorbs the high velocity flow from the valves, to merge it more smoothly with the low velocity flow of the half filled tunnel.
The ring had been damaged due to many years of use so earlier in 2009, they removed it.. (presumably with intent to replace). Then a few months later management thought it would be interesting to conduct a test to open the RVOS valve to 100% to see what effect it would have (1. they'd been told never to run it at 100% due to prior damage 2. design specs said RVOS was never to be operated without dispersion ring). The manually operated control (just a big wheel) for the RVOS cone valve sits in a chamber connected through a long person tunnel up into the inner turbine room, and that chamber is separated from the ring valve outlet by a fully sealed 20ft tall steel wall. That wall was designed to fail with 15ft of head pressure behind it in the unlikely event that the manual control valve failed and let water into that chamber. This wall failure would prevent water from backing up the person tunnel into the turbine room.
So.. 5 people enter the control room, and start to open the RVOS valve up to 100%. At 85% all hell breaks loose. The valves release about 4-5K CFS of water at extremely high velocity into a half filled tunnel, and without the dispersion ring this accelerates the velocity of the water in the tunnel for a few hundred feet. During original design (including extensive small scale testing), they realized that even with the dispersion ring a hydraulic jump could form as high velocity flow meets low, that might reach up to the roof of the tunnel, which could cause a vacuum condition in the tunnel upstream of the jump. So they built in a vent in the roof several hundred feet down the tunnel connected by a large tube running back to another vent in the cone valves outlet chamber. Idea being that if the jump formed between the two vents sealing the tunnel it could still equalize the air pressure on either side of it. But without the dispersion ring in place, the jump moved much further down the tunnel than design called for, and blocked the lower vent. This caused a siphon pump effect back to the valve outlet chamber, eventually causing high enough vacuum that the steel wall designed to hold back 15ft of water, blew out into the tunnel almost taking the 5 people in that chamber with it. Doors further up the man tunnel also failed and debris was sucked down that tunnel pelting the people in the chamber now open to raging water and continuing vacuum. With hurricane force winds coming from the person tunnel through the chamber into the RVOS outlet someone managed to turn off the valve to stop the flow. One person was seriously injured. RVOS was repaired in 2014, and operated again that year when drought conditions dropped the reservoir below the turbine inlets.
:O ......
Why tho? Why did they want to try that?
So what consequences did management face for reckless endangerment of 5 lives? Let me guess... a raise, promotion, transfer, or all three of the above.
@@allencummings7564 Short answer. They're idiots. Long answer according to the investigative report afterwards.. ""DWR removed the baffle ring in April 2009, four months before the test. It did so without consulting its Division of Dam Safety, which should have approved that action first. The test was ordered because DWR “wanted to determine the destructive effects” of opening the valves to 100 percent, according to the investigation."'
Mission accomplished.
Military application then?
I'm a kayaker and I clicked on this video because it reminded me of rapids and whitewater in rivers and then you explained it and even mentioned how we kayakers use this physical phenomenon to have fun! You explained it perfectly! Great video!
And a drowning machine
Another great video! The only thing I would have added is a little discussion about what the Froude number is in various flow regimes. It would be useful for Civil students and others interested in understanding these things.
I have an undergraduate degree in chemical engineering, a graduate degree in mechanical engineering, and another graduate degree in aerospace engineering where I studied hypersonic air breathing propulsion. And yet I learned absolutely NOTHING about hydraulic jump in school. I love learning new things so thank you so much for this video. :)
One of the very few channels that favor quality, not quantity.
Grady the type of guy to make a 100% overlooked phenomenon interesting and accessible.
normaly I would skip this video because the thumbnail couldn t get my attention but then I realized its a practical engineering video. Good work👍
Well, better that than emojis and OMG slapped all over it. I hate that crap.
Really nice explanation of the jump. I 'm an engineer for NJ and our erosion control program (urban; construction, storm water etc) deals with scour protection all the time. I'm going to forward a link to your video to our soil conservation districts for them to watch!
0:12
Right side: Lvl 1 turbulent flow
Left side: Lvl 100 *L A M I N A R F L O W*
_That's how fluid dynamics works_
I see you are a man of culture as well.
you deserve a medal
Lol have you been watching SmarterEveryDay?
Pewdiepie ft. Smarter everyday
Oh yeah yeah
I hope you’ll make a video about flow measurement.
So, how do they prevent the hydraulic jump structure from eroding?
Make it out of concrete ;)
I would imagine (in a dam example) that because the slipway and hydraulic jump section is generally exposed or near surface close to the dam, it is easy to work on it there and maintain or replace damaged sections, rather than trying to repair erosion downstream.
I suppose that, since the structure is already in that turbulence zone he is talking about (since the hidraulic jump starts ahead of the structure), the effects of the erosion had already stopped being important before that structure.
@@Fuyudo Concrete is not that resistant to flow erosion. Cavitation can break it very easily, even metal.
I think engineers would take that into consideration
“This is the definition of engineering…”
That was truly beautiful. Non- technical people might not realize that there is elegance and beauty in engineering. It blows me away sometimes.
Absolutely love your videos and how you make civil engineering so fun! Keep up the good work! Cheers!🙂
This was my favorite subject in civil engineering classes - hydraulics and fluid mechanics.
Fluid dynamics = "My feet slowly got wet."
Rocket science = "Big tube go real fast."
Got it. :)
Very nice video.
That's how I've learned it for many years in hydraulic and coastal Engineering
Greetings from Germany
“. . . So I built a flume in my garage!” Is one of the nerdiest exclamations I’ve ever heard.
Fascinating. thank you. I have a white water centre near me in Nth london and on my visits observing the canoeists i noticed that when exiting a 'rapid' they actually stayed where they were and didn't get pushed downstream. I was puzzled. I found your video and it goes some way to explaining why. Thanks again.
support your teachers. it's hard to find great teacher
Fluid dynamics is my fav subject and this video just incredibly made me more interested towards this subject. Thanks a lot.
At 01:15 what dam is that? Never seen it before and I love dams.
studinthemaking Right?! That's pretty gnarly looking.
One of the most useful channel on youtube, 100% scientific, No joke
When you see ocean waves coming on shore and then retreating, you can see a 'battle' between the receding and approaching waves, as mentioned in the video. Is that also a hydraulic jump? If yes, which is the tranquil bit and which is the fast bit?
Hey! I can see the dam on the Mississippi at 5:55 from my house! :) When he talked about the energy dissipation over a dam, I immediately thought of this one, because during snow melt in the spring, the river gets going really fast and the flowing water makes beautiful plumes of white water when it hits the bottom of the spillway.
Me: Lord, bless me with sleep at 03:45,
UA-cam: Tenuous engineering tutorial..?
Me: I’ll sleep when I’m dead; UA-cam; teach me.
5:55 that's where I live, Saint Anthony Falls on the Mississippi River in Minneapolis! I pass over that bridge on my way home every day and I love watching the water flow!
I thought rocket science was like 90% fluid dynamics. Moving metal thing through fluid (atmosphere), controlling and directing flow of fuel.
There's also a lot of material sciences involved.
From what I can tell, the main difference is the density of the fluid medium. The principles seem the same, they just happen at much lower speeds in water.
@@mikecurtin9831 water is also essentially incompressible
Moving stuff through fluids is aerodynamics, fluid dynamics deals with the motion of the fluid itself iirc. But I guess they're close enough.
And physics
As a student engineer, these videos are amazing for nailing theoretical engineering knowledge into awesome videos that solidify the science
Where is the dam from 1:11? :o Looks amazing, never seen such before
Huia Dam, perhaps. That's a bellmouth spillway.
The best and most useful channel on youtube PERIOD.
1:14 A nightmare for my over imaginative mind.
yeah, can you imagine standing on that catwalk looking directly down in the maw of that thing. geez.
Nope to the power of nope, noped.
You hit the nail on the head, nice to know I'm not the only one. I think my heart stopped & my mouth opened. What if? What if? What if?
Come on Georgie. We all float down here.
Same here. If you're feeling adventurous, check out this video. It starts out fascinating, but wait for what happens after the cameraman zooms onto the stairwell a couple minutes in: ua-cam.com/video/fJVBlhgt9j8/v-deo.html
It's during a regular test that shuts a valve near the turbine and what you see is holding tank to prevent a water hammer (which can cause damage to the water tunnels) from forming when the water tunnels to the turbine are closed. The uploader works at that dam, so check out his other videos, including down that hole on the right and a device (located up the incline) that is lowered down it to remove/replace the turbine blades.
Hello from the Dayton, Ohio area, where your footage around 1:50, 3:20, 5:22ish and 6:40 come from. Seeing that you report to be in Texas, these random shots from my local parks were an enjoyable surprise. :)
Being a civil engineer, I wish that you would have been my teacher in my college days😔😔
Glad to have a civvie who can explain open channel flow to this mechie. I've had a few false starts on reading up on hydraulic jump, but never really got anywhere. I've seen the sink example, but it didn't really give great insight like tying in subcritical and supercritical flow.
Also, I definitely experienced some low-key anxiety from the shot of the bellmouth spillway with the viewing platform right over the middle. Nothing like rolling a little acrophobia, bathophobia, submechanophobia, and a residual childhood fear of drains all into one! I also feel completely compelled to visit someday ... where is it?
In rocket science, there is a perfect analog: the shock wave. It also forces flow to go from supercritical to subcritical.
Thanks, you've got an absolute gift for explaining engineering theory clearly and concisely.
Does anything special happen when the flow is exactly critical or very close to it?
The height of the water becomes very variable.
Critical flow is also a very unstable condition that engineers seek to avoid when designing channels. You would ideally design the channel so that either the sub or super critical flow dominates, because as you approach critical flow conditions, the system as a whole becomes increasingly unpredictable
@@villageblunder4787: Thanks. It'd be interesting to see what that looks like.
I've just discovered this channel - I always wanted to be a Civil Engineer but ended up as a Chartered Surveyor - This channel is excellent and reinforces my view - I should have been a CEng.
Smarter Every Day channel talked about "laminar flow" this week, youd appreciate the video😎👍
I thought it was suspicious as well.
That hydraulic jump at 3:58 propagates just like a normal shock. This is so cool--I've never seen the analogy with supersonic flow so clearly! Just replace the sound speed with the surface wave velocity. So this really is rocket science!
What a complicated way to say "the water piles up against an obstacle"
Right. Like I said, it's intuitive and easy. This video tries to make it seem like something surprising. There are a lot of things in physics that I do find surprising. In fluid dynamics, I'd go with the Venturi effect and Mach diamonds. Elsewhere, gyroscopic precession, quantum locking. But this video spent nine breathless minutes saying "water piles up and the slow part ends up on top."
Love the way the information is presented
Those hydraulic jump spillways are also really dangerous. Not always a good compromise.
He was referring to dams with dissipation on the downstream side which prevent an abrupt hydraulic jump and prevent a retentive hole from forming to avoid erosion (and avoid a severe drowning hazard)
Tilman Baumann yep i almost died in one. glad i have an inflatable boat and not a canoe. see main comment for more info.😩🍻
Hi! I'm a whitewater kayaker who's tried some playboating in the past. It's super fun. I'm really glad you mentioned it in this video :) Thanks for posting!
Can someone please tell me where 1:12 is??😍😍
I want to know too.
Lower Huia Dam near Auckland, New Zealand. Found this in another post and verified with a Google search. www.cs.auckland.ac.nz/~bwue001/Tramping/LowerHuiaDamCircle/LowerHuiaDamCircle.html
I have seen a couple others too .... usually with some sort of fence to keep people out
No way, 5:01 is way better. 😍
Completely perfect demonstrations !!! Thanks.
Tashkent, Uzbekistan.
We need to get this channel to atleast a million subs
A Mechanical engineer
This guy's channel and its demonstration + crash course fan facts and animation + kurzgezagt philosophical approach and animation + khan academy/organic chemistry examples = ultra ideal tutorial video
1:11 You mean like the Oroville Dam?
I am so glad I found this channel. I've been fascinated by dams, weirs, watermills and basically everything that has something to do with large masses of water since I can remember.
1:20
Now, I'm not that young, and i don't know all the cool lingo the kids are using these days but I think it's fair to call that a #NOPEHOLE
69adrummer oww
Two months of fluid dynamics course packed into 8 mins! Thank you very much for this.
Neat
Man, i really love this channel. You are the best channel about engineering. A big shout out from Argentina!
watching this video made me thirsty.
also watching this video made me realize there is soooooo much water on earth.
I have seen Tidal bore a few times ( river Ganga)... it's quite common where I live!
Please make a video on tidal bores and rivers in general
Water flows 8 Blocks lol
LOL
LOL
I just wanna lay in your lap and soak up your knowledge and calming voice all night. Very informative video. I never imagined the fluid dynamic of a dam being as complex as you have exposed it to be.
in munich people surf the eisbach, i guess thats the same principle there
ok. but when comes HL3?
You give so correct practical knowledge
"Unlike rockets, you might have some intuitions about-"
Uh m8
You think I haven't played Kerbal Space Program?
one of the coolest videos on youtube. This video started getting me interested in fluid dynamics!
hydrolic jumps are also super dangerous please mention that somewhere before people drown while trying it out in a kayak
We have plenty of people. We can afford a few deaths by hydrolic jump.
If people want to nominate themselves for a Darwin Award, that's their business.
TheKazragore yeah well... I wasn’t aware that these were dangerous before a few years ago, they seem not completely friendly, but they are far more deadlier that they actually look... once you get stuck in one, you don’t get out
All kidding aside, the dangers of hydraulic jumps are not immediately obvious, and many of those killed are rescue personnel and even those trying to recover the bodies of rescue personnel.
As I'm seeing it, knowledge of what's happening mitigates most of the danger. Like with rip currents; for scuba divers they're a free ride out. The difference between safe and not is in recognizing and understanding what's going on. Without trying to be judgy, what makes things dangerous is ignorance and stupidity.
Ooh you did the video finally. Maybe you'll do another What's that Infrastructure video soon? I would also love to see more geotechnical videos with models like the internal erosion, ground water flow, and reinforced soil videos.
Very interesting engineering... definitly not duboius! :-)
Sir I came here from learn engineering. I am doing civil engineering. And I found your channel .Really amazing!!
I can't see the whole shirt, but methinks Grady is representing the HSV. ThinkerCon swag?
Awesome video. With simple but deep principles with far reaching real life implications, all explained in a compelling way. Thanks!!!
Just one note: gravity waves velocity is how fast pressure pressure disturbance travel --> how fast *hydrostatic* (or nearly hydrostatic) pressure disturbance travel (otherwise: sound speed is how fast pressure disturbance travel).
I'm thinking of being a civil engineer when I'm older but I don't know what qualifications I need
Please like this so that he will see it
I'm really enjoying your channel. I've been interested in infrastructure designs ever since I was a little kid. So, thank you!
This video would've been sooooooooo helpful during my 6th semester of college 😂
I wish I had you as my physics instructor in college. You explain things extremely well....great series of videos......
If you are looking to get married you should probably get a VPN...
Lmao upvoted, dude
Feynstein 100 “Upvoted” Ah I see you’re a man of culture as well
How relevant haha
Hi - Glad this came up on my YTube this morning. We have to design a drainage line from an uphill neighbor and I know some sort of gentling pond will be needed at the base of the steeper slope. This vid is helpful. A much smaller scale project, but "the principle is the same."
Intro music ???
You are the best! Explanations as vivid as these should be mandatory in fluid dynamics classes.
You know it’s that time of the month when your girlfriends flow goes from subcritical to supercritical
MidNight DarkChocolate LOL
Perhaps you should make her jump too ;)
Feynstein 100 Watch out for erosion tho
Tampons are the ultimate hydraulic jump
Umm, wouldn't that just cause the flow to be a lot heavier? I think supercritical would not be too bad to deal with.
Excellent demonstration and discussion, now my sidekick is pondering ideas for other ways to reduce water velocity.
"I owe my marriage to VPN..."
3:14 I'm new in the field of wastewater treatment and I'd LOVE to hear you talk more about how parshall flumes use fluid dynamics to measure flow.
Interestingly, you show us a hydraulic jump, but you never actually define what it is.
@Sunyata I know, but here again you also fail to explain what the 'jump' is. If you're going to try and explain something, maybe stand back a bit and look objectively at what you're saying. It's called a 'jump' because the surface level of the water just beyond the flow intersect is HIGHER at the sub-critical flow rate than it is at the critical flow that feeds it.
101
4:35 - Looks like a cold front. Neat!
"Fluid dynamics might sound as comlicated as rocket science..."
Boy i wish it was. Rocket science is weak shit when compared to fluid dynamics.
There's a reason why theres still a Millenium problem open on the Navier Stokes equation.
I like to have dangerous superficial knowledge! ;-)
You explain things so well, that I think to understand complex things after 5 minute videos.
Thanks a lot, you motivated to read books about fluid mechanics as a telecommunication engineer.
Nord vpn.....?????
Naaaahhhhh
I like nord lock washers
Great video. I just took my Fluid Mechanics course and am now taking Environmental Engineering course and this video was a great explanation of sub/super critical flow. 👍🏽